An additive manufacturing device utilizing an electron beam and laser integrated scanning comprises: a vacuum generating chamber (1); a worktable means having a forming region at least provided in the vacuum generating chamber (1); a powder supply means configured to supply a powder to the forming region; an electron-beam emission focusing and scanning means (6) and an laser-beam emission focusing and scanning means (7) configured in such a manner that a scanning range of the electron-beam emission focusing and scanning means (6) and a scanning range of the laser-beam emission focusing and scanning means (7) cover at least a part of the forming region; and a controller configured to control the electron-beam emission focusing and scanning means (6) and the laser-beam emission focusing and scanning means (7) to perform a powder integrated-scanning and forming treatment on the forming region.

A self-leveling container that contains argon gas for laser welding of a work piece includes a base surface, a plurality of pleated sidewalls, each comprising an associated distal sidewall end and an associated proximate sidewall end, where the proximate sidewall end is sealed to the base surface. A frame includes a plurality of frame segments, each secured to an associated one of the distal sidewall ends. A plurality of actuators, each located with one intersection of the plurality of frame segments, linearly move its associated one intersection of the plurality frame segments so a plane formed by the frame segments remains parallel to a planar surface.

A laser etching apparatus includes a chamber, a laser port, a laser emitter, a particle grabber, and a revolving window module. The chamber is configured to receive a substrate. The laser port is disposed below the chamber in a downward direction. The laser emitter is configured to emit a laser to the substrate disposed within the chamber through the laser port. The particle grabber is disposed within the chamber and includes a body disposed over the laser port. An opening is formed through the body. The opening is configured to pass the laser therethrough. The revolving window module includes a revolving window and a driving part configured to drive the revolving window. The revolving window is disposed between the particle grabber and the laser port.

A processing device for film cooling holes on blade of aviation engine includes a working box. A workpiece clamping mechanism is arranged in the working box for holding the workpiece. A cover body having an internal space communicated with an internal space of the working box is connected to an upper part of the working box. A laser processing mechanism is connected to a top end of the cover body and can produce laser rays to carry out laser processing on the workpiece. The cover body is connected to a liquid supply mechanism and an acid gas filtration mechanism. The liquid supply mechanism can spray an acidic solution to the workpiece in the working box, and the working box can collect the acidic solution. The acid gas filtration mechanism can filter acid steam produced during processing. A working method of the processing device is also provided.

An apparatus for gas mixing for a laser and/or air cutting machine. The apparatus includes a housing including a first inlet for nitrogen, a second inlet for oxygen, and an outlet for a gas mixture of the nitrogen and oxygen. A mixing unit including a mixer manifold between and connected to the gas outlet and each of the first and second inlets, the mixer manifold including a plurality of blending valves. A digital controller adjusts the plurality of blending valves, to achieve an oxygen percent in the gas mixture from about 0.5% to about 22%. A first oxygen percent of below 10% is generally useful for a laser cutter, and a second oxygen percent above 20% is generally useful for an air cutter. The gas mixture is provided at a pressure of about 33 to 35 bar, and the apparatus operates without a pressure blending or buffer tank, or further compressor.

An apparatus for gas mixing for a laser and/or air cutting machine. The apparatus includes a housing including a first inlet for nitrogen, a second inlet for oxygen, and an outlet for a gas mixture of the nitrogen and oxygen. A mixing unit including a mixer manifold between and connected to the gas outlet and each of the first and second inlets, the mixer manifold including a plurality of blending valves. A digital controller adjusts the plurality of blending valves, to achieve an oxygen percent in the gas mixture from about 0.5% to about 22%. A first oxygen percent of below 10% is generally useful for a laser cutter, and a second oxygen percent above 20% is generally useful for an air cutter. The gas mixture is provided at a pressure of about 33 to 35 bar, and the apparatus operates without a pressure blending or buffer tank, or further compressor.

A laser system includes a controller, a laser source, a laser scanner, and a laser containment apparatus. The laser containment apparatus includes a mounting structure for the laser scanner, a shroud assembly coupled to the mounting structure, and a seal interface coupled to the shroud assembly at an opposite end from the laser scanner. The shroud assembly surrounds a working volume of the laser scanner and includes a vacuum port connected to a vacuum source and a purge port that guides purge gas from a purge gas source toward the laser scanner. A distal end of the seal interface is formed of a pliable material that compresses to seal the shroud assembly to a target surface of a workpiece upon establishment of a negative pressure differential between a vacuum pressure inside the shroud assembly and ambient atmospheric pressure.

Systems for processing a material by submerging the material in a fluid and directing laser pulses at the fluid and the material for processing the material. An embodiment removes the surface of concrete, brick, or rock or minerals in a relatively gentle, energy-efficient, and controlled manner that also confines the material that is removed.

A module for an additive manufacturing apparatus including more than one optical train, each optical train providing a route for a laser beam to pass through the module and including steering optics for steering the laser beam towards the material to be consolidated as part of a layer-by-layer additive manufacturing process. The module is configured to deliver laser beams from the more than one optical trains through a single window in a build chamber of the additive manufacturing apparatus.

Provided is a mask changing unit for a laser bonding apparatus, and more particularly, a mask changing unit for a laser bonding apparatus, wherein the mask changing unit supplies or changes a mask to or in the laser bonding apparatus for bonding a semiconductor chip to a substrate by using a laser beam. The mask changing unit for a laser bonding apparatus, a plurality of masks that are used in performing laser bonding of a semiconductor chip to a substrate while the semiconductor chip is being pressed may be easily supplied to the laser bonding apparatus or changed in the laser bonding apparatus.